Litcius/Paper detail

Bridging granularity gaps to decarbonize large‐scale energy systems—The case of power system planning

Karl‐Kiên Cao, Jannik Haas, Evelyn Sperber, Shima Sasanpour, Seyedfarzad Sarfarazi, Thomas Pregger, Oussama Alaya, Hendrik Lens, Simon Ruben Drauz, T. Kneiske

2021Energy Science & Engineering19 citationsDOIOpen Access PDF

Abstract

Abstract The comprehensive evaluation of strategies for decarbonizing large‐scale energy systems requires insights from many different perspectives. In energy systems analysis, optimization models are widely used for this purpose. However, they are limited in incorporating all crucial aspects of such a complex system to be sustainably transformed. Hence, they differ in terms of their spatial, temporal, technological, and economic perspective and either have a narrow focus with high resolution or a broad scope with little detail. Against this background, we introduce the so‐called granularity gaps and discuss two possibilities to address them: increasing the resolutions of the established optimization models, and the different kinds of model coupling. After laying out open challenges, we propose a novel framework to design power systems in particular. Our exemplary concept exploits the capabilities of power system optimization, transmission network simulation, distribution grid planning, and agent‐based simulation. This integrated framework can serve to study the energy transition with greater comprehensibility and may be a blueprint for similar multimodel analyses.

Topics & Concepts

Computer scienceBlueprintBridging (networking)GranularityExploitScalabilityDistributed computingElectric power systemScope (computer science)GridSystems engineeringIndustrial engineeringData sciencePower (physics)EngineeringProgramming languageDatabaseQuantum mechanicsMathematicsMechanical engineeringOperating systemComputer securityGeometryComputer networkPhysicsIntegrated Energy Systems OptimizationElectric Power System OptimizationSmart Grid Energy Management